/*
 * Copyright (C) 2012 Open Source Robotics Foundation
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at
 *
 *     http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 *
*/
#ifndef GZ_MATH_VECTOR2_HH_
#define GZ_MATH_VECTOR2_HH_

#include <algorithm>
#include <cmath>
#include <istream>
#include <limits>
#include <ostream>

#include <gz/math/Helpers.hh>
#include <gz/math/config.hh>

namespace gz::math
{
  // Inline bracket to help doxygen filtering.
  inline namespace GZ_MATH_VERSION_NAMESPACE {
  //
  /// \class Vector2 Vector2.hh gz/math/Vector2.hh
  /// \brief Two dimensional (x, y) vector.
  template<typename T>
  class Vector2
  {
    /// \brief math::Vector2(0, 0)
    public: static const Vector2<T> &Zero;

    /// \brief math::Vector2(1, 1)
    public: static const Vector2<T> &One;

    /// \brief math::Vector2(NaN, NaN, NaN)
    public: static const Vector2 &NaN;

    /// \brief Default Constructor
    public: constexpr Vector2()
    : data{0, 0}
    {
    }

    /// \brief Constructor
    /// \param[in] _x value along x
    /// \param[in] _y value along y
    public: constexpr Vector2(const T &_x, const T &_y)
    : data{_x, _y}
    {
    }

    /// \brief Return the sum of the values
    /// \return the sum
    public: T Sum() const
    {
      return this->data[0] + this->data[1];
    }

    /// \brief Calc distance to the given point
    /// \param[in] _pt The point to measure to
    /// \return the distance
    public: double Distance(const Vector2 &_pt) const
    {
      return sqrt((this->data[0]-_pt[0])*(this->data[0]-_pt[0]) +
                  (this->data[1]-_pt[1])*(this->data[1]-_pt[1]));
    }

    /// \brief Returns the length (magnitude) of the vector
    /// \return The length
    public: T Length() const
    {
      return static_cast<T>(sqrt(this->SquaredLength()));
    }

    /// \brief Returns the square of the length (magnitude) of the vector
    /// \return The squared length
    public: T SquaredLength() const
    {
      return
        this->data[0] * this->data[0] +
        this->data[1] * this->data[1];
    }

    /// \brief Normalize the vector length
    public: void Normalize()
    {
      T d = this->Length();

      if (!equal<T>(d, static_cast<T>(0.0)))
      {
        this->data[0] /= d;
        this->data[1] /= d;
      }
    }

    /// \brief Returns a normalized vector
    /// \return unit length vector
    public: Vector2 Normalized() const
    {
      Vector2<T> result = *this;
      result.Normalize();
      return result;
    }

    /// \brief Round to near whole number, return the result.
    /// \return the result
    public: Vector2 Round()
    {
      this->data[0] = static_cast<T>(std::nearbyint(this->data[0]));
      this->data[1] = static_cast<T>(std::nearbyint(this->data[1]));
      return *this;
    }

    /// \brief Get a rounded version of this vector
    /// \return a rounded vector
    public: Vector2 Rounded() const
    {
      Vector2<T> result = *this;
      result.Round();
      return result;
    }

    /// \brief Set the contents of the vector
    /// \param[in] _x value along x
    /// \param[in] _y value along y
    public: void Set(T _x, T _y)
    {
      this->data[0] = _x;
      this->data[1] = _y;
    }

    /// \brief Get the dot product of this vector and _v
    /// \param[in] _v the vector
    /// \return The dot product
    public: T Dot(const Vector2<T> &_v) const
    {
      return (this->data[0] * _v[0]) + (this->data[1] * _v[1]);
    }

    /// \brief Get the absolute value of the vector
    /// \return a vector with positive elements
    public: Vector2 Abs() const
    {
      return Vector2(std::abs(this->data[0]),
                     std::abs(this->data[1]));
    }

    /// \brief Return the absolute dot product of this vector and
    /// another vector. This is similar to the Dot function, except the
    /// absolute value of each component of the vector is used.
    ///
    /// result = abs(x1 * x2) + abs(y1 * y2)
    ///
    /// \param[in] _v The vector
    /// \return The absolute dot product
    public: T AbsDot(const Vector2<T> &_v) const
    {
      return std::abs(this->data[0] * _v[0]) +
             std::abs(this->data[1] * _v[1]);
    }

     /// \brief Corrects any nan values
    public: inline void Correct()
    {
      // std::isfinite works with floating point values,
      // need to explicit cast to avoid ambiguity in vc++.
      if (!std::isfinite(static_cast<double>(this->data[0])))
        this->data[0] = 0;
      if (!std::isfinite(static_cast<double>(this->data[1])))
        this->data[1] = 0;
    }

    /// \brief Set this vector's components to the maximum of itself and the
    ///        passed in vector
    /// \param[in] _v the maximum clamping vector
    public: void Max(const Vector2<T> &_v)
    {
      this->data[0] = std::max(_v[0], this->data[0]);
      this->data[1] = std::max(_v[1], this->data[1]);
    }

    /// \brief Set this vector's components to the minimum of itself and the
    ///        passed in vector
    /// \param[in] _v the minimum clamping vector
    public: void Min(const Vector2<T> &_v)
    {
      this->data[0] = std::min(_v[0], this->data[0]);
      this->data[1] = std::min(_v[1], this->data[1]);
    }

    /// \brief Get the maximum value in the vector
    /// \return the maximum element
    public: T Max() const
    {
      return std::max(this->data[0], this->data[1]);
    }

    /// \brief Get the minimum value in the vector
    /// \return the minimum element
    public: T Min() const
    {
      return std::min(this->data[0], this->data[1]);
    }

    /// \brief Assignment operator
    /// \param[in] _v the value for x and y element
    /// \return this
    public: const Vector2 &operator=(T _v)
    {
      this->data[0] = _v;
      this->data[1] = _v;

      return *this;
    }

    /// \brief Addition operator
    /// \param[in] _v vector to add
    /// \return sum vector
    public: Vector2 operator+(const Vector2 &_v) const
    {
      return Vector2(this->data[0] + _v[0], this->data[1] + _v[1]);
    }

    /// \brief Addition assignment operator
    /// \param[in] _v the vector to add
    // \return this
    public: const Vector2 &operator+=(const Vector2 &_v)
    {
      this->data[0] += _v[0];
      this->data[1] += _v[1];

      return *this;
    }

    /// \brief Addition operators
    /// \param[in] _s the scalar addend
    /// \return sum vector
    public: inline Vector2<T> operator+(const T _s) const
    {
      return Vector2<T>(this->data[0] + _s,
                        this->data[1] + _s);
    }

    /// \brief Addition operators
    /// \param[in] _s the scalar addend
    /// \param[in] _v input vector
    /// \return sum vector
    public: friend inline Vector2<T> operator+(const T _s,
                                               const Vector2<T> &_v)
    {
      return _v + _s;
    }

    /// \brief Addition assignment operator
    /// \param[in] _s scalar addend
    /// \return this
    public: const Vector2<T> &operator+=(const T _s)
    {
      this->data[0] += _s;
      this->data[1] += _s;

      return *this;
    }

    /// \brief Negation operator
    /// \return negative of this vector
    public: inline Vector2 operator-() const
    {
      return Vector2(-this->data[0], -this->data[1]);
    }

    /// \brief Subtraction operator
    /// \param[in] _v the vector to substract
    /// \return the subtracted vector
    public: Vector2 operator-(const Vector2 &_v) const
    {
      return Vector2(this->data[0] - _v[0], this->data[1] - _v[1]);
    }

    /// \brief Subtraction assignment operator
    /// \param[in] _v the vector to substract
    /// \return this
    public: const Vector2 &operator-=(const Vector2 &_v)
    {
      this->data[0] -= _v[0];
      this->data[1] -= _v[1];

      return *this;
    }

    /// \brief Subtraction operators
    /// \param[in] _s the scalar subtrahend
    /// \return difference vector
    public: inline Vector2<T> operator-(const T _s) const
    {
      return Vector2<T>(this->data[0] - _s,
                        this->data[1] - _s);
    }

    /// \brief Subtraction operators
    /// \param[in] _s the scalar minuend
    /// \param[in] _v vector subtrahend
    /// \return difference vector
    public: friend inline Vector2<T> operator-(const T _s,
                                               const Vector2<T> &_v)
    {
      return {_s - _v.X(), _s - _v.Y()};
    }

    /// \brief Subtraction assignment operator
    /// \param[in] _s scalar subtrahend
    /// \return this
    public: const Vector2<T> &operator-=(T _s)
    {
      this->data[0] -= _s;
      this->data[1] -= _s;

      return *this;
    }

    /// \brief Division operator
    /// \remarks this is an element wise division
    /// \param[in] _v a vector
    /// \result a result
    public: const Vector2 operator/(const Vector2 &_v) const
    {
      return Vector2(this->data[0] / _v[0], this->data[1] / _v[1]);
    }

    /// \brief Division operator
    /// \remarks this is an element wise division
    /// \param[in] _v a vector
    /// \return this
    public: const Vector2 &operator/=(const Vector2 &_v)
    {
      this->data[0] /= _v[0];
      this->data[1] /= _v[1];

      return *this;
    }

    /// \brief Division operator
    /// \param[in] _v the value
    /// \return a vector
    public: const Vector2 operator/(T _v) const
    {
      return Vector2(this->data[0] / _v, this->data[1] / _v);
    }

    /// \brief Division operator
    /// \param[in] _v the divisor
    /// \return a vector
    public: const Vector2 &operator/=(T _v)
    {
      this->data[0] /= _v;
      this->data[1] /= _v;

      return *this;
    }

    /// \brief Multiplication operators
    /// \param[in] _v the vector
    /// \return the result
    public: const Vector2 operator*(const Vector2 &_v) const
    {
      return Vector2(this->data[0] * _v[0], this->data[1] * _v[1]);
    }

    /// \brief Multiplication assignment operator
    /// \remarks this is an element wise multiplication
    /// \param[in] _v the vector
    /// \return this
    public: const Vector2 &operator*=(const Vector2 &_v)
    {
      this->data[0] *= _v[0];
      this->data[1] *= _v[1];

      return *this;
    }

    /// \brief Multiplication operators
    /// \param[in] _v the scaling factor
    /// \return a scaled vector
    public: const Vector2 operator*(T _v) const
    {
      return Vector2(this->data[0] * _v, this->data[1] * _v);
    }

    /// \brief Scalar left multiplication operators
    /// \param[in] _s the scaling factor
    /// \param[in] _v the vector to scale
    /// \return a scaled vector
    public: friend inline const Vector2 operator*(const T _s,
                                                  const Vector2 &_v)
    {
      return Vector2(_v * _s);
    }

    /// \brief Multiplication assignment operator
    /// \param[in] _v the scaling factor
    /// \return a scaled vector
    public: const Vector2 &operator*=(T _v)
    {
      this->data[0] *= _v;
      this->data[1] *= _v;

      return *this;
    }

    /// \brief Equality test with tolerance.
    /// \param[in] _v the vector to compare to
    /// \param[in] _tol equality tolerance.
    /// \return true if the elements of the vectors are equal within
    /// the tolerence specified by _tol.
    public: bool Equal(const Vector2 &_v, const T &_tol) const
    {
      return equal<T>(this->data[0], _v[0], _tol)
          && equal<T>(this->data[1], _v[1], _tol);
    }

    /// \brief Equal to operator
    /// \param[in] _v the vector to compare to
    /// \return true if the elements of the 2 vectors are equal within
    /// a tolerence (1e-6)
    public: bool operator==(const Vector2 &_v) const
    {
      return this->Equal(_v, static_cast<T>(1e-6));
    }

    /// \brief Not equal to operator
    /// \return true if elements are of diffent values (tolerence 1e-6)
    public: bool operator!=(const Vector2 &_v) const
    {
      return !(*this == _v);
    }

    /// \brief See if a point is finite (e.g., not nan)
    /// \return true if finite, false otherwise
    public: bool IsFinite() const
    {
      // std::isfinite works with floating point values,
      // need to explicit cast to avoid ambiguity in vc++.
      return std::isfinite(static_cast<double>(this->data[0])) &&
             std::isfinite(static_cast<double>(this->data[1]));
    }

    /// \brief Array subscript operator
    /// \param[in] _index The index, where 0 == x and 1 == y.
    /// The index is clamped to the range [0,1].
    public: T &operator[](const std::size_t _index)
    {
      return this->data[clamp(_index, GZ_ZERO_SIZE_T, GZ_ONE_SIZE_T)];
    }

    /// \brief Const-qualified array subscript operator
    /// \param[in] _index The index, where 0 == x and 1 == y.
    /// The index is clamped to the range [0,1].
    public: T operator[](const std::size_t _index) const
    {
      return this->data[clamp(_index, GZ_ZERO_SIZE_T, GZ_ONE_SIZE_T)];
    }

    /// \brief Return the x value.
    /// \return Value of the X component.
    public: inline T X() const
    {
      return this->data[0];
    }

    /// \brief Return the y value.
    /// \return Value of the Y component.
    public: inline T Y() const
    {
      return this->data[1];
    }

    /// \brief Return a mutable x value.
    /// \return Value of the X component.
    public: inline T &X()
    {
      return this->data[0];
    }

    /// \brief Return a mutable y value.
    /// \return Value of the Y component.
    public: inline T &Y()
    {
      return this->data[1];
    }

    /// \brief Set the x value.
    /// \param[in] _v Value for the x component.
    public: inline void X(const T &_v)
    {
      this->data[0] = _v;
    }

    /// \brief Set the y value.
    /// \param[in] _v Value for the y component.
    public: inline void Y(const T &_v)
    {
      this->data[1] = _v;
    }

    /// \brief Stream extraction operator
    /// \param[out] _out output stream
    /// \param[in] _pt Vector2 to output
    /// \return The stream
    public: friend std::ostream
    &operator<<(std::ostream &_out, const Vector2<T> &_pt)
    {
      for (auto i : {0, 1})
      {
        if (i > 0)
          _out << " ";

        appendToStream(_out, _pt[i]);
      }
      return _out;
    }

    /// \brief Less than operator.
    /// \param[in] _pt Vector to compare.
    /// \return True if this vector's first or second value is less than
    /// the given vector's first or second value.
    public: bool operator<(const Vector2<T> &_pt) const
    {
      return this->data[0] < _pt[0] || this->data[1] < _pt[1];
    }

    /// \brief Stream extraction operator
    /// \param[in] _in input stream
    /// \param[in] _pt Vector2 to read values into
    /// \return The stream
    public: friend std::istream
    &operator>>(std::istream &_in, Vector2<T> &_pt)
    {
      T x, y;
      // Skip white spaces
      _in.setf(std::ios_base::skipws);
      _in >> x >> y;
      if (!_in.fail())
      {
        _pt.Set(x, y);
      }
      return _in;
    }

    /// \brief Underlying data pointer
    /// \remarks This method is intended for python bindings (numpy).
    /// \remarks The bounds-checking array subscript operator is much preferred
    /// for element access from C++.
    /// \return A pointer to the underlying data array.
    public: T* Data()
    {
      return this->data;
    }

    /// \brief The x and y values.
    private: T data[2];
  };

  namespace detail {

    template<typename T>
    constexpr Vector2<T> gVector2Zero(0, 0);

    template<typename T>
    constexpr Vector2<T> gVector2One(1, 1);

    template<typename T>
    constexpr Vector2<T> gVector2NaN(
        std::numeric_limits<T>::quiet_NaN(),
        std::numeric_limits<T>::quiet_NaN());

  }  // namespace detail

  template<typename T>
  const Vector2<T> &Vector2<T>::Zero = detail::gVector2Zero<T>;

  template<typename T>
  const Vector2<T> &Vector2<T>::One = detail::gVector2One<T>;

  template<typename T>
  const Vector2<T> &Vector2<T>::NaN = detail::gVector2NaN<T>;

  typedef Vector2<int> Vector2i;
  typedef Vector2<double> Vector2d;
  typedef Vector2<float> Vector2f;
  }  // namespace GZ_MATH_VERSION_NAMESPACE
}  // namespace gz::math
#endif  // GZ_MATH_VECTOR2_HH_
